KR101739583B1 - Fuel cell-engine hybrid power generation system with parallel reformer structure - Google Patents

Abstract

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a fuel cell-engine hybrid power generation system that performs power generation by using a fuel cell (Fuel Cell) and an engine in combination. According to the present invention, In order to solve the problems of conventional fuel cell-engine hybrid power generation systems in which there is a problem that heat energy flowing into a reformer becomes insufficient due to generation of electricity due to operating conditions, The fuel reformer is constituted by a parallel structure of a steam reforming (SR) reformer and a partial oxidation (POX) reformer, so that the operation and operation characteristics of the PO reformer, which is an endothermic SR reformer and the exothermic reaction, The reforming is carried out through the SR reformer having high efficiency, and the heat of the SR reformer In case of abnormal operation such as the case where the heat input to the SR reformer is lower than the normal range, the POX reformer, which is capable of driving in a short time and is accompanied by an exothermic reaction, is operated to perform reforming, A fuel cell-engine hybrid power generation system having a parallel reformer structure configured to be capable of actively responding to operating conditions to maintain stable operation at all times.

Description

TECHNICAL FIELD [0001] The present invention relates to a fuel cell-engine hybrid power generation system having a parallel reformer structure,

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a fuel cell-engine hybrid power generation system for distributed power generation that uses a fuel cell and an engine in combination, and more particularly, Engine hybrid power generation system having a parallel reformer structure configured to maintain stable operation at all times by solving the problems of conventional fuel cell-engine hybrid power generation systems in which there is a problem of insufficient heat energy.

Further, in order to solve the problem of the prior art fuel cell-engine hybrid power generation systems in which there is a problem of insufficient thermal energy flowing into the reformer according to operating conditions as described above, A fuel reformer is constructed in parallel with a steam reforming (SR) reformer and a partial oxidation (POX) reformer, so that the fuel reformer can actively respond to operating conditions, And more particularly, to a fuel cell-engine hybrid power generation system having a reformer structure.

In recent years, there has been an increasing demand for a more efficient power supply source capable of replacing existing energy due to the depletion of resources for fossil fuels such as petroleum, and the increasing demand for electric power due to the increasing industrialization and urbanization. A power generation system using a fuel cell has attracted attention.

These fuel cells mainly use hydrogen as a fuel, and there are two main methods of supplying hydrogen: direct use of hydrogen produced by electrolysis of water; and reforming of hydrocarbon-based fuel such as methanol, ethanol, and natural gas and the hydrogen produced by reforming is used.

That is, a power generation system using a fuel cell is a power generation system that converts the chemical reaction energy of hydrogen and oxygen directly into electrical energy. Depending on the type of the electrolyte used, a phosphoric acid fuel cell, a molten carbonate fuel cell, a solid oxide fuel cell , A polymer electrolyte type or an alkaline type fuel cell, and they are basically divided on the basis of the type of fuel used, the operating temperature, the catalyst, the electrolyte, and the like.

More particularly, a power generation system using a fuel cell generally includes a fuel supply device (such as a pump), a fuel reformer that reforms the fuel to generate hydrogen gas and supplies the generated hydrogen gas to the fuel cell When the fuel is supplied to the reformer by the fuel pump, the reformer reforms the fuel to generate hydrogen gas, and supplies the generated hydrogen to the fuel cell to electrochemically react the hydrogen gas and oxygen in the fuel cell Thereby generating electrical energy.

Therefore, when the fuel cell is used, heat is generated in the process of generating electricity by electrochemically reacting the fuel, so that it is possible to achieve a high efficiency of 80% or more in total efficiency, reduce fuel for power generation, In addition to eco-friendly power generation technology, which reduces NOx and CO2 emissions significantly compared to coal-fired power generation and low noise pollution, it can shorten the construction period by modularization, increase / decrease facility capacity, and facilitate site selection .

In addition, a fuel cell-based power generation system can be installed in an urban area or a building to provide an economical energy, and can use various fuels such as natural gas, city gas, methanol, and waste gas, And can be widely applied to power plants for distributed power sources, cogeneration power plants, pollution-free vehicle power sources, etc. In recent years, in addition to power generation by a fuel cell alone, power generation is performed in parallel with other means such as an engine, So-called hybrid power generation system is under study.

More specifically, as an example of the conventional technology for a hybrid power generation system using the fuel cell as described above, there is a hybrid power generation system using a fuel cell as described in Korean Patent Registration No. 10-1531291 According to the high-efficiency hybrid energy conversion system, a fuel cell that generates electric energy from an external fuel, a turbine that recovers the waste heat of the fuel cell to generate steam, generates steam by a compressor, A cogeneration system configured to circulate the energy generated by the turbine with a waste heat recoverer to be heat-exchanged to accumulate the fuel cells, the cogeneration system comprising: a power conditioning unit electrically connected to the fuel cell and the generator to store electric energy; And a distributor connected to the waste heat recoverer and thermally stored by mutual heat exchange An energy storage unit configured; An electricity generating unit electrically connected to the power conditioning to use the electric device; A heating generator for heating the heat exchanged with the distributor to exchange heat; And a cooling unit that can use the heat exchanged with the distributor and heat exchanged in the cooling device, so that the energy generated by the turbine and the fuel cell can be utilized not only in electricity, heat, A high-efficiency hybrid energy conversion system for complex loads has been proposed.

Further, according to another example of the conventional technology for a hybrid power generation system using the fuel cell as described above, for example, according to "DCFC-IGFC hybrid power generation system" as disclosed in Korean Patent Registration No. 10-14811587, A non-ashless coal production reactor for producing raw ash coal from raw coal and solvent; Ash coal supply line that supplies the ashless coal directly to the carbon fuel cell from the ashless coal production reactor; A direct carbon fuel cell that receives ash coal to the fuel electrode to generate electric energy; A pressurizing line for pressurizing the gas containing CO2 emitted from the fuel electrode of the direct carbon fuel cell and supplying it to the air flow transporting and supplying device; A coal supply line connected to the lower portion of the ashless coal production reactor to generate ashless coal and supply the remaining coal to the air flow transporting and feeding device; An air flow transporting device for air streaming the coal residues supplied from the coal residual supply line to the gas containing CO2 supplied through the pressurization line and supplying the coal to the gasifier; A gasifier that receives coal from the air flow transporting device and generates a synthesis gas; And a solid oxide fuel cell that generates electric energy by receiving the generated syngas, wherein the DCFC-IGFC includes a direct carbon fuel cell using ashless coal and a solid oxide fuel cell using residue coal. (Direct Carbon Fuel Cell-Integrated Gasification Fuel Cell) hybrid power generation system has been proposed.

Further, another example of the conventional technology for the hybrid power generation system using the fuel cell as described above is disclosed in Korean Patent Publication No. 10-1417951, entitled "Hybrid Hybrid Multiplication of Fuel Cell and Gas Engine According to the production system, in a hybrid hybrid cogeneration system that operates in conjunction with a cogeneration system using a fuel cell unit and a cogeneration system using a gas engine, water is electrolyzed using power generated from sunlight or wind power A fuel supply device for directly supplying produced hydrogen to the fuel cell section without going through a storage device; An oxygen storage tank for storing and utilizing oxygen produced by electrolyzing water using electric power generated from sunlight or wind power; A carbon dioxide storage tank for purifying, recovering, and pressurizing the exhaust gas through an exhaust gas processor for processing combustion exhaust gas generated when the cogeneration system is operated using the gas engine unit, thereby storing the carbon dioxide in a liquid state; A fuel cell including a compressor capable of being driven with surplus power generated during operation of a hybrid hybrid cogeneration system of a gas engine unit and a fuel cell unit, and configured to store and utilize oxygen and carbon dioxide produced through a compressor at high density; A hybrid hybrid multi-production system of a gas engine has been proposed.

Further, another example of the conventional technology for the hybrid power generation system using the fuel cell as described above is disclosed in Korean Patent Publication No. 10-0599685, for example, in "a reformer of a fuel cell system, According to the fuel cell system, a reformer that generates thermal energy through a chemical catalytic reaction and generates hydrogen gas from a fuel containing hydrogen; And at least one electricity generating unit for generating electric energy through an electrochemical reaction between hydrogen gas and oxygen, wherein the reformer has an internal space independent from each other, and a catalyst layer formed in each of the internal spaces, And a housing assembly which circulates the fuel to the outside of the reforming reaction part while covering the entire reforming reaction part, thereby improving the structure of the reformer, A reformer of a fuel cell system configured to improve the reaction efficiency and thermal efficiency for generating hydrogen, and a fuel cell system employing the same.

As described above, various technologies related to a hybrid power generation system using a fuel cell have been proposed. However, the conventional power generation systems using fuel cells as described above have the following problems.

That is, in general, a power generation system using a fuel cell is constituted by a heat circulation structure for supplying heat generated from the fuel cell back to a reformer, a heat exchanger, etc. For example, in the case of a hybrid system using an engine together with a fuel cell The fuel and high temperature gas used in the fuel cell are supplied to the engine to generate electricity, and the high temperature combustible gas discharged from the engine is supplied to the reformer and the heat exchanger to supply the heat required for the reforming.

In this case, the thermal energy supplied to the reformer may be insufficient depending on the operating conditions of the entire system, which may result in failure of the fuel cell to properly supply the required fuel. In this case, additional fuel To generate sufficient reforming gas, and to supply the necessary thermal energy in the entire system.

However, the fuel cell-engine hybrid power generation systems of the prior art have a problem in that the energy or the thermal energy of the fuel component supplied to the reformer is insufficient during the operation so that the operating conditions of the fuel cell system can be supplemented immediately Or means have not been proposed.

Therefore, in order to solve the problem of the prior art fuel cell-engine hybrid power generation systems in which there is a problem that the thermal energy supplied to the reformer becomes insufficient in accordance with operating conditions as described above, it is necessary to immediately supplement the thermal energy, It is desirable to propose a new structure of fuel cell-engine hybrid power generation system which is configured to be able to operate stably, but a device or a method that satisfies all of such requirements is not yet available.

[Prior Art Literature]

1. Korean Registered Patent No. 10-1531291 (Jun.

2. Korean Patent Registration No. 10-1481158 (December 30, 2014)

3. Korean Patent Publication No. 10-1417951 (Apr.

4. Korean Patent Registration No. 10-0599685 (2006.07.05.)

SUMMARY OF THE INVENTION The present invention has been made to solve the above problems of the conventional art and it is an object of the present invention to provide a fuel cell system and a fuel cell system, In order to solve the problem of the prior art fuel cell-engine hybrid power generation systems in which there is a problem of insufficient heat energy flowing into the fuel cell, the fuel reformer for reforming and supplying the fuel to the fuel cell is configured in a parallel structure, The present invention provides a fuel cell-engine hybrid power generation system having a parallel reformer structure configured to selectively operate each reformer to actively respond to operating conditions to maintain stable operation at all times.

It is another object of the present invention to provide a fuel cell system and a fuel cell system in which the fuel and heat remaining in the fuel cell are supplied to the engine to generate electricity, In order to solve problems of fuel cell-engine hybrid power generation systems, a fuel reformer for reforming and supplying a fuel to a fuel cell is constituted by a parallel structure of a steam reforming (SR) reformer and a partial oxidation (POX) reformer The reforming is performed using an SR reformer having a high efficiency in normal operation by using the operation characteristics and the starting characteristics of the endothermic SR reformer and the POX reformer as an exothermic reaction, Or when the heat input to the SR reformer is lower than the normal range, A reformer for reforming the reformed gas to reform the POX reformer, and a reformer for reforming the reformed gas to reform the POX reformer, Engine hybrid power generation system having a fuel cell-engine hybrid power generation system.

In order to achieve the above object, according to the present invention, there is provided a fuel cell-engine hybrid power generation system having a parallel reformer structure, comprising: a fuel cell unit including at least one fuel cell; A fuel reforming unit including a plurality of reformers for reforming and supplying the fuel to the fuel cell unit; And at least one engine for burning exhaust gas generated from the fuel cell unit to generate additional electricity, thereby selectively operating each of the reformers according to an operation state of the power generation system The fuel cell system is configured to be able to maintain a stable operation at all times.

Here, the fuel cell unit may include a high temperature fuel cell including a molten carbonate fuel cell (MCFC) or a solid oxide fuel cell (SOFC).

The fuel reforming unit may include at least one steam reforming unit and a partial oxidation unit, which are connected in parallel.

Further, the fuel reforming unit may perform the reforming through the SR reformer having good efficiency during normal operation, using the operating characteristics and the startup characteristics of the POX reformer accompanied by the exothermic reaction with the SR reformer accompanied by the endothermic reaction The PO reformer is activated to perform the reforming at the time of starting the SR reformer or in an abnormal operation in which the heat introduced into the SR reformer is lower than the normal range so that the reformed gas can be supplemented immediately, And is configured to be able to maintain stable operation at all times by selectively driving each reformer according to the operating state of the power generation system.

Further, the engine unit is configured by using a HCCI (Homogeneous Charge Compression Ignition) engine.

According to another aspect of the present invention, there is provided a method of operating a fuel cell-engine hybrid power generation system using the above-described fuel cell-engine hybrid power generation system, comprising: operating the SR reformer and the POX reformer of the fuel cell- Simultaneously driving the POX reformer until the SR reformer reaches a normal operating range; Performing reforming through the SR reformer in normal operation; And a step of operating the POX reformer to immediately supplement the deficient reformed gas when the heat input to the SR reformer becomes insufficient in accordance with operating conditions, Wherein the SR reformer and the POX reformer are selectively operated to maintain a stable operation at all times. The present invention also provides a method of operating a fuel cell-engine hybrid power generation system.

As described above, according to the present invention, the fuel reformer for reforming and supplying the fuel to the fuel cell has a parallel structure, and the fuel having the parallel reformer structure configured to selectively operate each reformer according to the operation state The battery-engine hybrid power generation system is provided with the fuel cell and the fuel cell. The fuel cell and the fuel cell are connected to each other through the fuel cell. The problem of the engine hybrid generation system can be solved.

According to the present invention, as described above, the fuel reformer for reforming and supplying the fuel to the fuel cell comprises a parallel structure of a steam reforming (SR) reformer and a partial oxidation (POX) reformer, In the normal operation, the reforming is performed by using the SR reformer having high efficiency by using the operation characteristic and the starting characteristic of the PO reformer, which is the reaction of the SR reformer and the exothermic reaction, and the SR In the case of abnormal operation such as the case where the heat input to the reformer is lower than the normal range, the POX reformer, which can be driven in a short time and is accompanied by an exothermic reaction, is activated to perform reforming so as to instantaneously replenish the deficient reformed gas The fuel cell-engine hybrid power generation system having the parallel reformer structure is provided, So that stable operation can be maintained at all times.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a schematic view showing a general configuration of a conventional fuel cell-engine hybrid power generation system; FIG.
2 is a diagram schematically showing the overall configuration of a fuel cell-engine hybrid power generation system having a parallel reformer structure according to an embodiment of the present invention.
3 is a view schematically showing a specific configuration of a fuel reforming unit of a fuel cell-engine hybrid power generation system having a parallel reformer structure according to an embodiment of the present invention shown in FIG.

Hereinafter, a fuel cell-engine hybrid power generation system having a parallel reformer structure according to the present invention will be described with reference to the accompanying drawings.

Hereinafter, it is to be noted that the following description is only an embodiment for carrying out the present invention, and the present invention is not limited to the contents of the embodiments described below.

In the following description of the embodiments of the present invention, parts that are the same as or similar to those of the prior art, or which can be easily understood and practiced by a person skilled in the art, It is important to bear in mind that we omit.

That is, according to the present invention, as described later, there is a problem in that there is a problem that heat energy flowing into the reformer becomes insufficient due to operating conditions by generating electricity by supplying fuel and heat remaining in the fuel cell to the engine, In order to solve the problems of the fuel cell-engine hybrid power generation systems of the present invention, the fuel reformer for reforming and supplying the fuel to the fuel cell is configured in a parallel structure, thereby selectively operating each reformer according to the operation state, And more particularly, to a fuel cell-engine hybrid power generation system having a parallel reformer structure that can be actively responded to in accordance with a power factor of a fuel cell.

In addition, the present invention provides a fuel cell of the prior art in which the problem of insufficient heat energy flowing into the reformer due to operating conditions is caused by supplying electricity to the engine by supplying fuel and heat remaining in the fuel cell, In order to solve the problems of the engine hybrid power generation systems, a fuel reformer for reforming and supplying the fuel to the fuel cell is constituted by a parallel structure of a steam reforming (SR) reformer and a partial oxidation (POX) reformer, In the normal operation, the reforming is performed using the SR reformer having high efficiency by using the operation characteristic and the starting characteristic of the endothermic SR reformer and the POX reformer, which is an exothermic reaction. In the case of starting with insufficient heat to be supplied to the SR reformer In the case of abnormal operation such as when the heat input to the SR reformer is lower than the normal range, And a POX reformer with an exothermic reaction is operated to perform reforming to immediately supplement the deficient reformed gas so that the POX reformer can actively respond to operating conditions to maintain stable operation at all times. Fuel cell-engine hybrid power generation system.

Next, the fuel cell-engine hybrid power generation system having the above-described parallel reformer structure according to the embodiment of the present invention constructed as described above will be described in detail with reference to the drawings.

Referring first to FIG. 1, FIG. 1 is a schematic view of a general configuration of a conventional fuel cell-engine hybrid power generation system.

 1, a conventional fuel cell-engine hybrid power generation system 10 generally includes a fuel cell unit 11 including at least one fuel cell unit, A fuel reforming unit 12 including a reformer for reforming and supplying fuel to the fuel cell 11 and an engine for burning exhaust gas generated from the fuel cell unit 11 to generate additional electricity And an engine unit 13 which is provided with an engine.

1, the conventional fuel cell-engine hybrid power generation system 10 includes a fuel tank and a fuel pump for supplying fuel, an air supply means for supplying air, a cooling water supply means A plurality of heat exchangers for overall thermal circulation in the system, a water separator for separating water and gas from the exhaust gas generated in the fuel cell unit 11 and supplying the separated water and gas to the engine unit 13, And power conversion means such as an inverter for converting the generated direct current into alternating current.

More specifically, the fuel cell provided in the fuel cell unit 11 includes a cathode portion in which oxygen molecules are decomposed into oxygen ions (O ₂ -) and electrons, and a cathode portion in which hydrogen molecules and oxygen ions And an anode where electricity is generated by generating water and reacting to produce electricity by supplying fuel and air from the outside.

That is, the fuel cell installed in the fuel cell unit 11 may be a high temperature fuel such as a solid oxide fuel cell (SOFC), a molten carbonate fuel cell (MCFC) A battery can be used.

In addition, in addition to the above, the fuel cell unit 11 may further include internal reforming means for reforming the fuel in the fuel cell itself, as shown in FIG.

Furthermore, the fuel reforming unit 12 described above can supply hydrogen (LNG, LPG, methane, methanol or the like) or a synthesis gas (coal gas or the like) containing a part of hydrogen to a large amount of hydrogen And to supply hydrogen to the anode of the fuel cell.

Here, the reformer installed in the fuel reforming unit 12 generally takes a long time to warm up, but has a high efficiency. Therefore, a steam reforming (SR) reformer is often used.

Next, an HCCI (Homogeneous Charge Compression ignition) engine may be preferably used as the engine installed in the engine section 12 described above.

More specifically, at the anode of the fuel cell unit 11, an exhaust gas containing water and carbon dioxide is supplied through an electrochemical oxidation reaction with hydrogen supplied from a reformer and oxygen ions supplied from a cathode part, Gas and electricity are generated, and there are the following problems on the assumption that a diesel engine is used, for example, in order to use such exhaust gas for combustion.

That is, in general, a diesel engine injects a liquid fuel at a high pressure of about 20: 1 to induce an explosion. This is because diesel fuel including light oil causes self-explosion at a temperature of 400 to 500 ° C., The combustion rate of the fuel is increased and the fuel efficiency is improved. However, in the case of the power generation system using the fuel cell, the concentration of the exhaust gas discharged from the anode is higher than that of the liquid fuel used in the diesel engine Concentration, and furthermore, it is not easy to compress and discharge the exhaust gas in a gaseous state at a high pressure because energy consumption is large.

Considering the case of using a gasoline engine in order to avoid the problems of the above-described diesel engine, for example, in the case of a gasoline engine in which an ignition device explodes by sparking an air- Since the ignition is difficult with only the fuel gas discharged from the fuel cell having a low carbon monoxide ratio, there is a disadvantage that the additional fuel must be supplied. Thus, the addition of the additional fuel means a decrease in efficiency of the entire system.

However, when the HCCI engine is used in the engine section 12 as described above, the HCCI engine is an engine having only the advantages of a gasoline engine and a diesel engine. Even if the ratio of hydrogen to carbon monoxide is low, Since the ratio of hydrogen to carbon monoxide is low, the combustion temperature is lowered and the generation of nitrogen oxides can be prevented.

Therefore, the operation of the fuel cell-engine hybrid electric power generation system configured as described above is such that when the fuel and air modified through the fuel reforming unit 12 are supplied to the fuel cell unit 11, Electricity is produced by the electrochemical reaction of the cell.

In addition, at the same time, the exhaust gas generated from the anode of the fuel cell unit 11 is removed from the gas component by removing part of the water component through the water separator, separating the whole water component from the gas, The generator is operated by using the explosion force generated when the mixed gas of the anode off gas supplied to the engine section 13 and the air supplied from the outside is ignited in the engine section 13, In addition, additional electricity can be produced.

In addition, the heat of the exhaust gas generated by the engine 13 is directly supplied to the fuel reforming unit 12, and the remaining heat that has passed through the reformer is used for heating or hot water through the heat exchanger, The heat of the exhaust gas discharged from the engine unit 13 can be recycled and the efficiency of the entire system can be improved.

Here, a more specific configuration and operation of the fuel cell-engine hybrid power generation system 10 as shown in FIG. 1 is obvious to those skilled in the art with reference to the literature of the prior art, and therefore, It should be noted that the same or similar contents are not described in detail.

As described above, when the fuel cell-engine hybrid power generation system 10 configured as shown in FIG. 1 is used, the total amount of power generation and efficiency can be increased by a dual structure of the fuel cell and the engine. However, In the conventional fuel cell-engine hybrid power generation system 10, fuel and heat generated in the fuel cell are supplied to the engine and power generation is performed, thereby causing fluctuations in the heat flowing into the reformer.

In addition, when the heat flowing into the reformer is changed to cause insufficient heat, it is necessary to immediately supplement the insufficient heat in order to prevent the normal operation of the reformer from being impossible. For this purpose, for example, It is undesirable to have the heating means of the system as a whole because the structure is complicated and the cost is increased, thereby causing many disadvantages such as increased installation and operation costs and inefficiency.

In order to solve the problems of the conventional fuel cell-engine hybrid power generation system 10 as described above, the present invention provides a fuel reforming unit having a parallel structure including a plurality of reformers, The present invention provides a fuel cell-engine hybrid power generation system of a new structure that is structured to be capable of actively responding even when heat is fluctuated and to maintain stable operation at all times.

2 is a schematic view showing the overall configuration of a fuel cell-engine hybrid power generation system 20 having a parallel reformer structure according to an embodiment of the present invention.

Hereinafter, in the embodiment of the present invention described below, the same or similar components as those of the conventional fuel cell-engine hybrid power generation system 10 described above with reference to FIG. 1 will be described in detail in order to simplify the description We should keep in mind that we omitted.

2, a fuel cell-engine hybrid power generation system 20 having a parallel reformer structure according to an embodiment of the present invention roughly includes a fuel cell unit including at least one fuel cell unit And a reformer for reforming and supplying the fuel to the fuel cell unit 21 and a reformer for burning the exhaust gas generated in the fuel cell unit 11 to generate additional Engine hybrid power generation system 10 shown in FIG. 1 in that it includes an engine section 23 including at least one engine for producing electricity.

2, the fuel cell-engine hybrid power generation system 20 having the parallel reformer structure according to the embodiment of the present invention includes a fuel tank and a fuel pump for supplying fuel, A cooling water supply means for supplying cooling water, a plurality of heat exchangers for overall thermal circulation in the system, and a heat exchanger for separating water and gas from the exhaust gas generated in the fuel cell unit 21 and supplying the water and gas to the engine unit 23 And a power conversion means such as an inverter for converting the direct current generated in the fuel cell unit 21 into an alternating current and the like can be constructed by referring to FIG. And is similar to the battery-engine hybrid power generation system 10.

However, in the fuel cell-engine hybrid power generation system 20 having the parallel reformer structure according to the embodiment of the present invention, a plurality of reformers for reforming the fuel are provided in the fuel cell unit 21, In the present invention.

That is, the fuel reforming unit 22 includes a fuel reforming unit 22, for example, by connecting a steam reforming (SR) reformer and a partial oxidation (POX) reformer in parallel, The POX reformer, which has a shorter preheating time, is used in the case of starting with insufficient heat to be supplied to the SR by using the operating characteristic and the starting characteristic of the endothermic reaction SR and the exothermic POX, In the abnormal operation such as when the heat input to the reformer is lower than the normal range according to the operating condition, the POX reformer accompanied by the exothermic reaction is operated to immediately supplement the deficient reformed gas. As a result, So that it is possible to maintain stable operation at all times and actively cope with the operation conditions.

3, a specific configuration of the fuel reforming unit 22 of the fuel cell-engine hybrid power generation system 20 having the parallel reformer structure according to the embodiment of the present invention shown in FIG. 2 is shown in FIG. Fig.

3, the fuel reforming unit 22 of the fuel cell-engine hybrid power generation system 20 having the parallel reformer structure according to the embodiment of the present invention includes an SR A reformer 31, and a POX reformer 32 having an advantage of short preheating time accompanied by an exothermic reaction.

3, by connecting the SR reformer 31 and the POX reformer 32 in parallel, the characteristics of the SR reformer 31, which is an endothermic reaction, and the POX reformer 32, which is an exothermic reaction, When the reforming is carried out through the SR reformer 31 having a high efficiency and when the heat is supplied to the SR reformer 31 and the heat input to the SR reformer 31 is lower than the normal range The POX reformer 32 which can be driven in a short time during the abnormal operation and is activated by the POX reformer 32 accompanied by the exothermic reaction can be constructed so as to immediately supplement the deficient reformed gas.

As described above, when the fuel cell-engine hybrid power generation system 20 having the parallel reformer structure according to the embodiment of the present invention is used, the SR reformer 31 having a high efficiency and the POX reformer 32 capable of being driven in a short time are provided. The PO reformer 32 is driven to start the SR reformer 31 at the time of the initial startup and the reformed gas is reformed through the SR reformer 31 at the normal operation, The reformer 32 is operated again to immediately supplement the deficient reformed gas, so that it is possible to actively cope with the operating conditions according to the operating conditions Stable operation can be maintained.

In addition, in the fuel cell-engine hybrid power generation system 20 having the parallel reformer structure according to the embodiment of the present invention shown in FIGS. 2 and 3, It should be noted that the detailed description of the same or similar parts to those of the conventional art is omitted here for simplicity of description.

Accordingly, the fuel cell-engine hybrid power generation system having the parallel reformer structure according to the present invention can be implemented as described above.

Also, by implementing the fuel cell-engine hybrid power generation system having the parallel reformer structure according to the present invention as described above, according to the present invention, the fuel reformer for reforming and supplying the fuel to the fuel cell has a parallel structure The fuel cell-engine hybrid power generation system has a parallel reformer structure configured to selectively operate a reformer according to an operating state of the fuel cell, thereby generating electricity by supplying fuel and heat remaining in the fuel cell to the engine The problems of conventional fuel cell-engine hybrid power generation systems in which there is a problem of insufficient heat energy flowing into the reformer depending on operating conditions can be solved.

In addition, according to the present invention, as described above, the fuel reformer for reforming and supplying the fuel to the fuel cell comprises a parallel structure of a steam reforming (SR) reformer and a partial oxidation (POX) reformer, In the normal operation, the reforming is performed by using the SR reformer having high efficiency by using the operation characteristic and the starting characteristic of the PO reformer, which is the reaction of the SR reformer and the exothermic reaction, and the SR In the case of abnormal operation such as the case where the heat input to the reformer is lower than the normal range, the POX reformer, which can be driven in a short time and is accompanied by an exothermic reaction, is activated to perform reforming so as to instantaneously replenish the deficient reformed gas The fuel cell-engine hybrid power generation system having the parallel reformer structure, It is possible to cope dynamically and always maintain a stable operation.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments. It will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the present invention as defined by the following claims and their equivalents. would.

10. Fuel Cell - Engine Hybrid Generation System
11. Fuel cell section 12. Fuel reform section
13. Engine section
20. Fuel cell-engine hybrid power generation system having a parallel reformer structure
21. Fuel cell section 22. Fuel reform section
23. Engine part 31. SR reformer
32. POX reformer

Claims (6)

1. A fuel cell-engine hybrid power generation system having a parallel reformer structure,
A fuel cell comprising at least one fuel cell;
A fuel reforming unit including a plurality of reformers for reforming and supplying the fuel to the fuel cell unit; And
And at least one engine for generating additional electricity by burning the exhaust gas generated in the fuel cell unit,
The fuel reforming unit includes:
At least one Steam Reforming (SR) reformer and a Partial Oxidation (POX) reformer are connected in parallel,
Reforming is performed through the SR reformer having good efficiency at normal operation by using the operation characteristics and the startup characteristics of the POX reformer accompanied by the exothermic reaction with the SR reformer accompanied by the endothermic reaction, The reformer is configured to start up the POX reformer and perform the reforming operation to immediately supplement the deficient reformed gas when the heat input to the SR reformer is lower than the normal range,
Wherein the reformer is configured to selectively operate each of the reformers according to an operation state of the power generation system so as to maintain a stable operation at all times.
The method according to claim 1,
The fuel cell unit includes:
Wherein the high-temperature fuel cell comprises a high-temperature fuel cell including a molten carbonate fuel cell (MCFC) or a solid oxide fuel cell (SOFC).
delete delete The method according to claim 1,
The engine unit includes:
Wherein the fuel cell is configured using an HCCI (Homogeneous Charge Compression Ignition) engine.
An operating method of a fuel cell-engine hybrid power generation system using the fuel cell-engine hybrid power generation system according to any one of claims 1 to 7,
Simultaneously driving the SR reformer and the POX reformer of the fuel cell-engine hybrid power generation system at the time of initial startup, and driving the POX reformer auxiliaryly until the SR reformer reaches a normal operation range;
Performing reforming through the SR reformer in normal operation; And
And a step of activating the POX reformer to immediately supplement the deficient reformed gas when the heat input to the SR reformer becomes insufficient depending on operating conditions,
Engine hybrid power generation system according to an embodiment of the present invention; FIG. 2 is a block diagram of a fuel cell system according to a first embodiment of the present invention; FIG. How to drive.

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